Electrical treatment of Alzheimer&#39;s disease

ABSTRACT

A method is provided that includes disposing midplane treatment electrodes over a superior sagittal sinus, outside and in electrical contact with a skull of a head of a subject identified as at risk of or suffering from Alzheimer&#39;s disease. Lateral treatment electrodes are disposed between 1 and 12 cm of a sagittal midplane of the skull. The subject is treated by electroosmotically driving fluid from a subarachnoid space to the superior sagittal sinus, by activating control circuitry to apply one or more treatment currents between (a) one or more of the midplane treatment electrodes and (b) one or sore of the lateral treatment electrodes. Other embodiments are also described. Other embodiments are also described.

FIELD OF THE APPLICATION

The present invention relates generally to treatment and prevention ofAlzheimer's diseases, and specifically to electrical techniques fortreating and preventing Alzheimer's disease.

BACKGROUND OF THE APPLICATION

Alzheimer's disease is a chronic neurodegenerative disease that causesdementia. Accumulation of amyloid beta in the brain is widely believedto contribute to the development of Alzheimer's disease.

SUMMARY OF THE APPLICATION

Embodiments of the present invention provide a system, and methods fortreating Alzheimer's disease. The system comprises a plurality ofmidplane treatment electrodes, a plurality of lateral treatmentelectrodes, and control circuitry, which is electrically coupled to thetreatment electrodes. For some applications, a method for treatingAlzheimer's disease comprises:

-   -   disposing the midplane treatment electrodes over a superior        sagittal sinus, outside and in electrical contact with a skull        of a head of a subject identified as at risk of or suffering        from Alzheimer's disease;    -   disposing the lateral treatment electrodes between 1 and 12 cm        of a sagittal midplane of the skull; and    -   treating the subject by electroosmotically driving fluid from a        subarachnoid space to the superior sagittal sinus, by activating        the control circuitry to apply one or more treatment currents        between (a) one or more of the midplane treatment electrodes        and (b) one or more of the lateral treatment electrodes.

For some applications, treating the subject comprises facilitatingclearance of amyloid beta from the subarachnoid space to the superiorsagittal sinus by electroosmotically driving the fluid from thesubarachnoid space to the superior sagittal sinus. Alternatively oradditionally, for some applications, treating the subject comprisesfacilitating clearance of metal ions from the subarachnoid space to thesuperior sagittal sinus by electroosmotically driving the fluid frontthe subarachnoid space to the superior sagittal sinus.

Avoiding insertion of midplane treatment electrodes into the superiorsagittal sinus may reduce any risks associated with implantation andoperation of the system.

Typically, the control circuitry is activated to configure the midplanetreatment electrodes as cathodes, and the lateral treatment electrodesas anodes. For some applications, the control circuitry is activated toindependently apply the treatment currents between respective pairs ofthe midplane and the lateral treatment electrodes.

For some applications, the one or more treatment currents applied usingthe midplane and the lateral treatment electrodes pass between thesubarachnoid space and the superior sagittal sinus, via inferolateralsurfaces of the superior sagittal sinus. For these applications, thelocations of the midplane treatment electrodes and/or the lateraltreatment electrodes are typically selected such that the one or moretreatment currents pass through the inferolateral surfaces. For example,for configurations in which the lateral treatment electrodes aredisposed outside and in electrical contact with the skull, the lateraltreatment electrodes may be disposed between 5 and 12 cm of the sagittalmidplane of the skull; for configurations in which the lateral treatmentelectrodes are implanted under an arachnoid mater of the subject, thelateral treatment electrodes may be disposed between 1 and 3 cm of thesagittal midplane of the skull.

For some applications, the midplane treatment electrodes are disposedoutside the head, such as on an external surface of the head. For otherapplications, the midplane treatment electrodes are implanted under skinof the head. For some applications, the system further comprises amidplane lead, along which the midplane treatment electrodes aredisposed (e.g., fixed).

For some applications, the lateral treatment electrodes are disposedoutside and in electrical contact with the skull. For some of theseapplications, the lateral treatment electrodes are disposed outside thehead, such as on the external surface of the head, or are implantedunder the skin of the head.

For some applications, the lateral treatment electrodes comprise leftlateral treatment electrodes and right lateral treatment electrodes. Theleft lateral treatment electrodes are disposed left of the sagittalmidplane of the skull, and the right lateral treatment electrodes aredisposed right of the sagittal midplane of the skull. For someapplications, the control circuitry is activated to configure themidplane treatment electrodes as cathodes, and the left and the rightlateral treatment electrodes as left and right anodes. respectively.

For some applications, the lateral treatment electrodes are implantedunder arachnoid mater of the subject, such as in the subarachnoid spaceor in gray or white matter of a brain of the subject.

There is therefore provided, in accordance with an application of thepresent invention, a method including:

disposing midplane treatment electrodes over a superior sagittal sinus,outside and in electrical contact with a skull of a head of a subjectidentified as at risk of or suffering from Alzheimer's disease;

disposing lateral treatment electrodes between 1 and 12 cm of asagittal, midplane of the skull; and

treating the subject by electroosmotically driving fluid from asubarachnoid space to the superior sagittal sinus, by activating controlcircuitry to apply one or more treatment currents between (a) one ormore of the midplane treatment electrodes and (b) one or more of thelateral treatment electrodes.

For some applications, treating the subject includes facilitatingclearance of amyloid beta from the subarachnoid space to the superiorsagittal, sinus by electroosmotically driving the fluid from thesubarachnoid space to the superior sagittal sinus. Alternatively oradditionally, for some applications, treating the subject includesfacilitating clearance of metal ions from the subarachnoid space to thesuperior sagittal sinus by electroosmoticaily driving the fluid from thesubarachnoid space to the superior sagittal sinus.

For some applications, activating the control circuitry includesactivating the control circuitry to apply the one or more treatmentcurrents with an average amplitude of between 1 and 3 milliamps.

For some applications, disposing the lateral treatment electrodesincludes disposing the lateral treatment electrodes outside and inelectrical contact with the skull. For some applications, disposing thelateral treatment electrodes includes disposing the lateral treatmentelectrodes between 4 and 12 cm of the sagittal midplane of the skull.For some applications, disposing the midplane and the lateral treatmentelectrodes includes disposing each of the lateral treatment electrodesbetween 1 and 12 cm of at least one of the midplane treatmentelectrodes. For some applications, disposing the midplane and thelateral treatment electrodes includes disposing each of the lateraltreatment electrodes between 1 and 12 cm of one of the midplanetreatment electrodes that is closest to the lateral treatment electrode.

For some applications, disposing the lateral treatment electrodesincludes disposing the lateral treatment electrodes outside the head.For some applications, disposing the lateral treatment electrodesincludes disposing the lateral treatment electrodes on an externalsurface of the head. For some applications, disposing the lateraltreatment electrodes includes implanting the lateral treatmentelectrodes under skin of the head.

For some applications, disposing the midplane treatment electrodesincludes disposing the midplane treatment electrodes outside the head.For some applications, disposing the midplane treatment electrodesincludes disposing the midplane treatment electrodes on an externalsurface of the head. For some applications, disposing the midplanetreatment electrodes includes implanting the midplane treatmentelectrodes under skin of the head.

For some applications, disposing the lateral treatment electrodesincludes implanting the lateral treatment electrodes under an arachnoidmater of the subject. For some applications, disposing the lateraltreatment electrodes includes disposing the lateral treatment electrodesbetween 1 and 3 cm of the sagittal midplane of the skull. For someapplications, disposing the midplane and the lateral treatmentelectrodes includes disposing each of the lateral treatment electrodesbetween 1 and 3 cm of at least one of the midplane treatment electrodes.For some applications, disposing the midplane and the lateral treatmentelectrodes includes disposing each of the lateral treatment electrodesbetween 1 and 3 cm of one of the midplane treatment electrodes that isclosest to the lateral treatment electrode. For some applications,disposing the lateral treatment electrodes includes disposing thelateral treatment electrodes in the subarachnoid space. For someapplications, disposing the lateral treatment electrodes includesdisposing the lateral treatment electrodes in gray or white matter of abrain of the subject.

For some applications, disposing the midplane treatment electrodesincludes disposing the midplane treatment electrodes within 10 mm of thesagittal midplane of the skull.

For some applications, the method further includes implanting thecontrol circuitry under skin of the subject.

For some applications, disposing the midplane treatment electrodesincludes disposing the midplane treatment electrodes such that at leastone of the midplane treatment, electrodes is at least 5 mm from anotherone of the midplane treatment electrodes. For some applications,disposing the lateral treatment electrodes includes disposing thelateral treatment electrodes such that at least one of the lateraltreatment electrodes is at least 5 mm from another one of the lateraltreatment electrodes.

For some applications, disposing the midplane treatment electrodesincludes disposing at least five midplane treatment electrodes over thesuperior sagittal sinus. For some applications, disposing the lateraltreatment electrodes includes disposing at least five lateral treatmentelectrodes between 1 and 12 cm of the sagittal midplane of the skull.

For some applications:

disposing the midplane treatment electrodes includes disposing amidplane lead outside the skull, and the midplane treatment electrodesare disposed along the midplane lead, and

disposing the lateral treatment electrodes includes disposing a laterallead within 1 and 12 cm of the sagittal midplane of the skull, and thelateral treatment electrodes are disposed along the lateral lead.

For some applications, activating the control circuitry includesactivating the control circuitry to configure the midplane treatmentelectrodes as cathodes, and the lateral treatment electrodes as anodes.

For some applications:

the lateral treatment electrodes include left lateral treatmentelectrodes and right lateral treatment electrodes, and

disposing the lateral treatment electrodes includes disposing the leftlateral treatment electrodes left of the sagittal midplane of the skull,and disposing the right lateral treatment electrodes right of thesagittal midplane of the skull.

For some applications, activating the control circuitry includesactivating the control circuitry to configure the midplane treatmentelectrodes as cathodes, and the left and the right lateral treatmentelectrodes as left and right anodes, respectively.

For some applications:

disposing the left lateral treatment electrodes includes disposing theleft lateral treatment electrodes such that at least one of the leftlateral treatment electrodes is at least 1 cm from another one of theleft lateral treatment electrodes, and

disposing the right lateral treatment electrodes includes disposing theright lateral treatment electrodes such that at least one of the rightlateral treatment electrodes is at least 1 cm from another one of theright lateral treatment electrodes.

For some applications:

disposing the left lateral treatment electrodes includes disposing atleast five left lateral treatment electrodes left of the sagittalmidplane of the skull, and

disposing the right lateral treatment electrodes includes disposing atleast five right lateral treatment electrodes right of the sagittalmidplane of the skull.

For some applications:

disposing the midplane treatment electrodes includes disposing amidplane lead outside the skull, and the midplane treatment electrodesare disposed along the lead,

disposing the left lateral treatment electrodes includes disposing aleft lateral lead outside the skull, and the left lateral treatmentelectrodes are disposed along the left lateral lead, and

disposing the right lateral treatment electrodes includes disposing aright lateral lead outside the skull, and the right lateral treatmentelectrodes are disposed along the right lateral lead.

For some applications, activating the control circuitry to apply the oneor more treatment currents between (a) one or more of the midplanetreatment electrodes and (b) one or more or the lateral treatmentelectrodes includes activating the control circuitry to apply:

a first treatment current between a first one of the midplane treatmentelectrodes and a first one of the left lateral treatment electrodes,

a second treatment current between the first one of the midplanetreatment electrodes and a first one of the right lateral treatmentelectrodes,

a third treatment current between a second one of the midplane treatmentelectrodes and a second one of the left lateral treatment electrodes,and

a fourth treatment current between the second one of the midplanetreatment electrodes and a second one of the right lateral treatmentelectrodes.

For some applications, activating the control circuitry includesactivating the control circuitry to configure the midplane treatmentelectrodes as cathodes, and the left and the right lateral treatmentelectrodes as left and right anodes, respectively.

For some applications, electroosmotically driving the fluid includes:

detecting, by the control circuitry, a voltage difference between thesubarachnoid space and the superior sagittal sinus; and

setting, by the control circuitry, a level of the one or more treatmentcurrents responsively to the detected voltage difference.

For some applications:

the method further includes implanting a single first detectionelectrode in the subarachnoid space, and a single second detectionelectrode in the superior sagittal sinus, and

detecting the voltage includes detecting, by the control circuitry, thevoltage difference between the first and the second detectionelectrodes.

For some applications, activating the control circuitry includesactivating the control circuitry to apply the one or more treatmentcurrents as direct current. For some applications, activating thecontrol circuitry includes activating the control circuitry to apply theone or more direct currents as a plurality of pulses.

There is further provided, in accordance with an application of thepresent invention, a method including:

disposing one or more midplane treatment electrodes over a superiorsagittal sinus, outside and in electrical contact with a skull of a headof a subject identified as at risk of or suffering from Alzheimer'sdisease;

disposing one or more lateral treatment electrodes between 1 and 12 cmof a sagittal midplane of the skull; and

treating the subject by electroosmotically driving fluid from asubarachnoid space to the superior sagittal sinus, by activating controlcircuitry to apply one or more treatment currents between (a) one ormore of the midplane treatment electrodes and (b) one or more of thelateral treatment electrodes.

For some applications:

the one or more lateral treatment electrodes include one or more leftlateral treatment electrodes and one or more right lateral treatmentelectrodes, and

disposing the one or more lateral treatment electrodes includesdisposing the one or more left lateral treatment electrodes left of thesagittal midplane of the skull, and disposing the one or more rightlateral treatment electrodes right of the sagittal midplane of theskull.

For some applications, activating the control circuitry includesactivating the control circuitry to configure the one or more midplanetreatment electrodes as one or more cathodes, the one or more leftlateral treatment electrodes as one or more left anodes, and the one ormore right lateral treatment electrodes as one or more right anodes.

For some applications, the one or more midplane treatment electrodesinclude an elongate electrode having a length of at least 10 cm. Forsome applications, the one or more lateral treatment electrodes includean elongate electrode having a length of at least 10 cm.

There is further provided, in accordance with an application of thepresent invention, apparatus for treating a subject identified as atrisk of or suffering from Alzheimer's disease, the apparatus including:

exactly three leads, consisting of a midplane lead, a left lateral lead,and a right lateral lead;

at least five midplane electrodes, which are disposed along the midplanelead at an average distance of at least 1 cm betweenlongitudinally-adjacent pairs of the midplane electrodes, measuredbetween longitudinal midpoints of the midplane electrodes;

at least five left lateral electrodes, which are disposed along the leftlateral lead at an average distance of at least 1 cm betweenlongitudinally-adjacent pairs of the left lateral electrodes, measuredbetween longitudinal midpoints of the left lateral electrodes;

at least five right lateral electrodes, which are disposed along theright lateral lead at an average distance of at least 1 cm betweenlongitudinally-adjacent pairs of the right lateral electrodes, measuredbetween longitudinal midpoints of the right lateral electrodes; and

a housing, which includes control circuitry, to which the midplane, theleft lateral, and the right lateral electrodes are electrically coupledvia the midplane lead, the left lateral lead, and the right laterallead, respectively, the control circuitry configured to:

-   -   configure the midplane treatment electrodes as cathodes, and the        left and the right lateral treatment electrodes as left and        right anodes, respectively,    -   apply respective treatment currents between (a) (i) one or more        of the midplane treatment electrodes and (ii) one or more of the        left lateral treatment electrodes, and (b) (i) one or more of        the midplane treatment electrodes and (ii) one or more of the        right lateral treatment electrodes, and    -   configure the treatment currents to treat the subject by        electroosmotically driving fluid from a subarachnoid space to a        superior sagittal sinus of the subject.

For some applications, the control circuitry is configured to apply thetreatment currents with an average amplitude of between 1 and 3milliamps.

For some applications, the housing is configured to be implanted underskin of the subject.

For some applications, the control circuitry is configured to apply:

a first treatment current between a first one of the midplane treatmentelectrodes and a first one of the left lateral treatment electrodes,

a second treatment current between the first one of the midplanetreatment electrodes and a first one of the right lateral treatmentelectrodes,

a third treatment current between a second, one of the midplanetreatment electrodes and a second one of the left lateral treatmentelectrodes, and

a fourth treatment current between the second one of the midplanetreatment electrodes and a second one of the right lateral treatmentelectrodes.

For some applications, the control circuitry is configured to:

detect a voltage difference between the subarachnoid space and thesuperior sagittal sinus; and

set a level of the treatment currents responsively to the detectedvoltage difference.

For some applications, the control circuitry is configured to apply thetreatment currents as direct current. For some applications, the controlcircuitry is configured to apply the direct currents as a plurality ofpulses.

The present invention will be more fully understood from the followingdetailed description of embodiments thereof, taken together with thedrawings, in which:

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-B are schematic illustration of a system for treatingAlzheimer's disease, in accordance with respective applications of thepresent invention;

FIG. 2 is a schematic illustration of another configuration of thesystem of FIGS. 1A-B, in accordance with an application of the presentinvention;

FIG. 3 is a schematic illustration of yet another configuration of thesystem of FIG. 1A, in accordance with an application of the presentinvention; and

FIG. 4 is a schematic illustration of the system of FIGS. 1A-B, inaccordance with an application of the present invention.

DETAILED DESCRIPTION OF APPLICATIONS

FIGS. 1A-B are schematic illustration of a system 20 for treatingAlzheimer's disease, in accordance with respective applications of thepresent invention. System 20 comprises a plurality of midplane treatmentelectrodes 30, such as at least 5, no more than 20, and/or between 5 and20 midplane treatment electrodes 30. System 20 further comprises aplurality of lateral treatment electrodes 32, such as at least 5, nomore than 40, and/or between 5 and 40 lateral treatment electrodes 32,such as between 5 and 20 lateral treatment electrodes 32, or between 10and 40 lateral treatment electrodes. For some applications, the numberof each type of treatment electrode is determined based on the size ofthe head of the subject. For some applications, system 20 comprisestwice as many lateral treatment electrodes 32 as midplane treatmentelectrodes 30. System 20 further comprises control circuitry 34, whichis electrically coupled to the treatment electrodes.

For some applications, a method for treating Alzheimer's diseasecomprises:

-   -   disposing midplane treatment electrodes 30 over a superior        sagittal sinus 40, outside and in electrical contact with a        skull 42 of a head 44 of a subject identified as at risk of or        suffering from Alzheimer's disease;    -   disposing lateral treatment electrodes 32 at a distance D1 of        between 1 and 12 cm of a sagittal midplane 46 of skull 42        (labeled in FIG. 1B; distance D1 is measured in a straight line        from a closest portion of each treatment electrode to sagittal        midplane 46, rather than along the curvature of skull 42); and    -   treating the subject by electroosmotically driving fluid from a        subarachnoid space 50 to superior sagittal sinus 40, by        activating control circuitry 34 to apply one or more treatment        currents between (a) one or more of midplane treatment        electrodes 30 and (b) one or more of lateral treatment        electrodes 32 (each of the treatment currents is schematically        illustrated in the figures by a plurality of current lines 52).

As used in the present application, including in the claims, “over thesuperior sagittal sinus” means aligned with the superior sagittal sinusat a location more superficial than the superior sagittal sinus, i.e.,at a greater distance from a center of the head. As used in the presentapplication, including the claims, “treating” includes both treating asubject already diagnosed with Alzheimer's disease, as well aspreventing the development of Alzheimer's disease in a subject notdiagnosed with the disease and/or asymptomatic for the disease.

For some applications, treating the subject comprises facilitatingclearance of amyloid beta from subarachnoid space 50 to superiorsagittal sinus 40 by electroosmoticaily driving the fluid fromsubarachnoid space 50 to superior sagittal sinus 40. Alternatively oradditionally, for some applications, treating the subject comprisesfacilitating clearance of metal ions from subarachnoid space 50 tosuperior sagittal sinus 40 by electroosmoticaily driving the fluid fromsubarachnoid space 50 to superior sagittal sinus 40. Application of thetreatment currents causes a potential difference between subarachnoidspace 50 and superior sagittal sinus 40, which causes movement of theamyloid beta and/or metal ions from subarachnoid space 50 to superiorsagittal sinus 40.

For some applications, the one or more treatment currents applied usingmidplane treatment electrodes 30 and lateral treatment electrodes 32pass between subarachnoid space 50 and superior sagittal sinus 40, viainferolateral surfaces 54 of superior sagittal sinus 40, For some ofthese applications, at least 40%, e.g., at least 75% or at least 90%, ofthe treatment currents pass between subarachnoid space 50 and superiorsagittal sinus 40, via inferolateral surfaces 54 of superior sagittalsinus 40. For the applications described immediately above, thelocations of midplane treatment electrodes 30 and/or lateral treatmentelectrodes 32 are typically selected such that the one or more treatmentcurrents pass through inferolateral surfaces 54. For example, forconfigurations in which lateral treatment electrodes 32 are disposedoutside and in electrical contact with skull 42, such as described withreference to FIGS. 1A-B, lateral treatment electrodes 32 may be disposedat distance D1 of least 4 cm, no more than 12 cm, and/or between 4 and12 cm of sagittal midplane 46 of skull 42; for configurations in whichlateral treatment electrodes 32 are implanted under an arachnoid mater100 of the subject, such as described with reference to FIG. 2, lateraltreatment electrodes 32 may be disposed at least 1 cm, no more than 3cm, and/or between 1 and 3 cm of sagittal midplane 46 of skull 42.

Typically, control circuitry 34 is activated to configure midplanetreatment electrodes 30 as cathodes, and lateral treatment electrodes 32as anodes.

Alternatively, for some applications, control circuitry 34 is activatedto configure midplane treatment electrodes 30 as anodes, and lateraltreatment electrodes 32 as cathodes, such as for electroosmoticallydriving fluid from superior sagittal sinus 40 to subarachnoid space 50.

For some applications, at least five midplane treatment electrodes 30are disposed over superior sagittal sinus 40. Alternatively oradditionally, for some applications, at least five lateral treatmentelectrodes 32 between 1 and 12 cm of sagittal midplane 46 of skull 42.For some applications, each of lateral treatment electrodes 32 isdisposed between 1 and 12 cm of at least one of midplane treatmentelectrodes 30.

For some applications, midplane treatment electrodes 30 are disposedwithin 10 mm of sagittal midplane 46 of skull 42. Alternatively oradditionally, for some applications, midplane treatment electrodes 30are disposed such that at least one of midplane treatment electrodes 30is at least 5 mm from another one of midplane treatment electrodes 30,no more than 20 mm from another one of midplane treatment electrodes 30,and/or between 5 and 30 mm from another one of midplane treatmentelectrodes 30. For some applications, at least one of lateral treatmentelectrodes 32 is disposed is at least 5 mm from another one of lateraltreatment electrodes 32.

For some applications, such as shown in FIG. 1A, midplane treatmentelectrodes 30 are implanted under skin 62 of head 44. For otherapplications, such as shown in FIG. 1B, midplane treatment electrodes 30are disposed, outside head 44, such as on an external surface 60 of head44. For some applications, system 20 further comprises a midplane lead70, along which midplane treatment electrodes 30 are disposed (e.g.,fixed). Midplane lead 70 is disposed outside skull 42 in order todispose midplane treatment electrodes 30 over superior sagittal sinus40. For some applications in which midplane treatment electrodes 30 areimplanted under skin 62, the implantation is performed by introducingmidplane lead 70 through an incision in skin 62, typically at aposterior site of the head, and tunneling the midplane lead toward ananterior site of the head, such as near the forehead. Optionally, eachof midplane treatment electrodes 30 is inserted through a respectiveincision in skin 62, and connected to midplane lead 70.

For some applications, the method further comprises implanting controlcircuitry 34 under skin of the subject, such as under skin 62 of head44, or elsewhere in the subject's body.

For some applications, such as shown in FIGS. 1A-B, lateral treatmentelectrodes 32 are disposed outside and in electrical contact with skull42. For some of these applications, lateral treatment electrodes 32 areimplanted under skin 62 of head 44, such as shown in FIG. 1A.Alternatively, lateral treatment electrodes 32 are disposed outside head44, such as on external surface 60 of head 44, such as shown in FIG. 1B.For some of these applications, lateral treatment electrodes 32 may bedisposed at least 4 cm, no more than 12 cm, and/or between 4 and 12 cmof sagittal midplane 46 of skull 42. (As used in the presentapplication, including in the claims, all specified ranges include theirendpoints.) Such positioning may generate one or more treatment currentsthat pass between subarachnoid space 50 and superior sagittal sinus 40,via inferolateral surfaces 54 of superior sagittal sinus 40, asdescribed above. For some applications, system 20 further comprises alateral lead 72, along which lateral treatment electrodes 32 aredisposed (e.g., fixed). Lateral lead 72 is disposed outside skull 42,typically within 1 and 12 cm of sagittal midplane 46 of skull 42, inorder to dispose lateral treatment electrodes 32. For some applicationsin which lateral treatment electrodes 32 are implanted under skin 62,the implantation is performed by introducing lateral lead 72 through anincision in skin 62, typically at a posterior site of the head, andtunneling the lateral lead toward an anterior site of the head, such asnear the forehead. Optionally, each of lateral treatment electrodes 32is inserted through a respective incision in skin 62, and connected tolateral lead 72. For some applications, instead of providing laterallead 72, lateral treatment electrodes 32 are instead coupled to midplanelead 70. Midplane lead 70 is introduced with the lateral electrodesconstrained, and, the lateral electrodes are configured upon release toextend laterally, typically automatically. This configuration may alsobe used for applications in which both left and right lateral electrodesare provided, as described hereinbelow.

For some applications, control circuitry 34 is activated toindependently apply the treatment currents between respective pairs ofmidplane treatment electrodes 30 and lateral treatment electrodes 32.Such independent application of the currents allows continued effectiveoperation of system 20 even if a low resistance should develop betweenthe electrodes of one of the pairs (e.g., because of anatomicalvariations). For some of these applications, in order to enable suchindependent application of the currents, midplane lead 70 comprises aplurality of conductive wires corresponding to a number of midplanetreatment electrodes 30, and lateral lead 72 comprises a plurality ofconductive wires corresponding to a number of lateral treatmentelectrodes 32. Alternatively, control circuitry 34 and the electrodesimplement electrical multiplexing, as is known in the art, in which caseeach of the leads need only comprise a single conductive wire.Alternatively, for some applications, all of midplane treatmentelectrodes 30 are electrically coupled to one another such as by asingle conductive wire in the midplane lead), and all of lateraltreatment electrodes 32 are electrically coupled to one other (such asby a single conductive wire in the lateral lead).

For some applications of the configuration shown in FIG. 1B, system 20further comprises one or more thin elongate support elements 64, whichcouple lateral leads 72 to midplane lead 70, in order to provide properspacing and alignment between the midplane electrodes and the lateralelectrodes. Support elements 64 are typically non-conductive.

For some applications, control circuitry 34 is configured to apply theone or more treatment currents with an average amplitude of between 1and 3 milliamps. (The resulting voltage is typically greater in theconfiguration shown in FIGS. 1A-B than in the configuration shown inFIG. 2, because the one or more treatment currents pass through skull 42twice.)

For some applications, control circuitry 34 is activated to apply theone or more treatment currents as direct current, typically as aplurality of pulses, for example at greater than 500 Hz and/or less than2 kHz, e.g., at 1 kHz. For some applications, a duty cycle of the pulsesis above 90%, and for some applications pulses are not used but insteadan effective duty cycle of 100% is utilized. Typically, but notnecessarily, the duty cycle is 90% or lower, because a given level ofapplied voltage produces higher current in the tissue if the capacitancein the tissue is allowed to discharge between pulses.

For some applications, control circuitry 34 is activated to apply theone or more treatment currents in sessions, each of which has a durationof several seconds or several minutes, or continuously for longerperiods (e.g., 30 minutes). For some applications, the one or moretreatment currents are not applied for a period that is at least amhour. Optionally, control circuitry 34 is activated to apply the one ormore treatment currents only when the subject is sleeping, such as toinhibit any sensations that may be associated with application of theone or more treatment currents. For some applications, power foractivating and/or charging control circuitry 34 is transmitted from awireless energy transmitter in a hat, such as described hereinbelow withreference to FIG. 3, or from a wireless energy transmitter in, under, orabove a mattress. For some applications, control circuitry 34 isactivated to apply the one or more treatment currents according to apre-selected schedule, such as a duty cycle, such as for a few hours perday. For example, control circuitry 34 may be configured to becontrolled and/or powered by an extracorporeal control circuitry, suchas a control circuitry comprising a wireless transmitter, disposed inand/or in the vicinity of the subject's bed. For some applications, oneor more rest periods during which the treatment voltage is not appliedare provided in the pre-selected schedule.

For some applications, lateral treatment electrodes 32 comprise leftlateral treatment electrodes 32A and right lateral treatment electrodes32B. Left lateral treatment electrodes 32A are disposed left of sagittalmidplane 46 of skull 42, and right lateral treatment electrodes 32B aredisposed right of sagittal midplane 46 of skull 42. For someapplications, control circuitry 34 is activated to configure midplanetreatment electrodes 30 as cathodes, and left and right lateraltreatment electrodes 32A and 32B as left and right anodes, respectively.

For some applications, left lateral treatment electrodes 32A aredisposed such that at least one of left lateral treatment electrodes 32Ais at least 1 cm, no more than 5 cm, and/or between 1 and 5 cm (e.g., 3cm) from another one of left lateral treatment electrodes 32A,and/orright lateral treatment electrodes 32B are disposed such that atleast one of right lateral treatment electrodes 32B is at least 1 cm, nomore than 5 cm, and/or between 1 and 5 cm (e.g., 3 cm) from another oneof right lateral treatment electrodes 32B. Alternatively oradditionally, for some applications, left lateral treatment electrodes32A are disposed such that, longitudinally-adjacent ones of theelectrodes are disposed at least 1 cm, no more than 5 cm, and/or between1 and 5 cm (e.g., 3 cm) from each other, and/or right lateral treatmentelectrodes 32B are disposed such that longitudinally-adjacent ones ofthe electrodes are disposed at least 1 cm, no more than 5 cm, and/orbetween 1 and 5 cm (e.g., 3 cm) from each other. For some applications,at least five left lateral treatment electrodes 32A are disposed left ofsagittal midplane 46 of skull 42, and/or at least five right lateraltreatment electrodes 32B are disposed right of sagittal midplane 46 ofskull 42.

As mentioned above, for some applications, system 20 further comprisesmidplane lead 70, along which midplane treatment electrodes 30 aredisposed (e.g., fixed). Midplane lead 70 is disposed outside skull 42 inorder to dispose midplane treatment electrodes 30. For some of theseapplications, system 20 further comprises (a) a left lateral lead 72A,along which left lateral treatment electrodes 32A are disposed (e.g.,fixed), and (b) a right lateral lead 72B, along which right lateraltreatment electrodes 32B are disposed (e.g., fixed). Left lateral lead72A is disposed outside skull 42, typically within 1 and 12 cm ofsagittal midplane 46 of skull 42, in order to dispose left lateraltreatment electrodes 32A. Right lateral lead 728 is disposed outsideskull 42, typically within 1 and 12 cm of sagittal midplane 46 of skull42, in order to dispose right lateral treatment electrodes 32B.

For some applications, control circuitry 34 is activated toindependently apply the treatment currents between respective pairs ofmidplane and left lateral treatment electrodes 30 and 32A, and betweenrespective pairs of midplane and right lateral treatment electrodes 30and 32B. For example, control circuitry 34 may be activated to apply thetreatment, currents between each of the midplane treatment electrodes 30and both (a) a corresponding one of left lateral treatment electrodes32A and (b) a corresponding one of right lateral treatment electrodes32B. For some of these applications, in order to enable such independentapplication of the treatment currents, midplane lead 70 comprises aplurality of conductive wires corresponding to a number of midplanetreatment electrodes 30, left lateral lead 72A comprises a plurality ofconductive wires corresponding to a number of left lateral treatmentelectrodes 32A, and right lateral lead 72B comprises a plurality ofconductive wires corresponding to a number of right lateral treatmentelectrodes 32B. Alternatively, control circuitry 34 and the electrodesimplement electrical multiplexing, as is known in the art, in which caseeach of the leads need only comprise a single conductive wire.Alternatively, for some applications, all of midplane treatmentelectrodes 30 are electrically coupled to one other (such as by a singleconductive wire in the midplane lead), all of left lateral treatmentelectrodes 32A are electrically coupled to one other (such as by asingle conductive wire in the left lateral lead), and all of rightlateral treatment electrodes 32B are electrically coupled to one other(such as by a single conductive wire in the right lateral lead).

For example, control circuitry 34 may be activated to apply:

-   -   a first treatment current between a first one of midplane        treatment electrodes 30 and a first one of left lateral        treatment electrodes 32A,    -   a second treatment current between the first one of midplane        treatment electrodes 30 and a first one of right lateral        treatment electrodes 32B,    -   a third treatment current between a second one of midplane        treatment electrodes 30 and a second one of left lateral        treatment electrodes 32A, and    -   a fourth treatment current between the second one of midplane        treatment electrodes 30 and a second one of right lateral        treatment electrodes 32B.

Typically, control circuitry 34 is activated to configure midplanetreatment electrodes 30 as cathodes, and left and right lateraltreatment electrodes 32A and 32B as left and right anodes, respectively.

Reference is now made to FIG. 2, which is a schematic illustration ofanother configuration of system 20, in accordance with an application ofthe present invention. In this configuration, lateral treatmentelectrodes 32 are implanted under arachnoid mater 100 of the subject,such as in subarachnoid space 50, in gray matter 102, or in white matterof a brain 104 of the subject. For example, lateral treatment electrodes32 may comprise needle electrodes, as is known in the art. Thisconfiguration may implement any of the techniques described hereinabovewith reference to FIGS. 1A-B, mutatis mutandis.

For some of these applications, lateral treatment electrodes 32 aredisposed at least 1 cm, no more than 3 cm, and/or between 1 and 3 cm ofsagittal midplane 46 of skull 42. Such positioning may generate thetreatment currents that pass between subarachnoid space 50 and superiorsagittal sinus 40, via inferolateral surfaces 54 of superior sagittalsinus 40, as described above. For some applications, each of lateraltreatment electrodes 32 is disposed between 1 and 3 cm of at least oneof midplane treatment electrodes 30. For some applications, each oflateral treatment electrodes 32 is disposed between 1 and 3 cm of one ofmidplane treatment electrodes 30 that is closest to the lateraltreatment electrodes.

For some applications, a surgical technique for implanting lateraltreatment electrodes 32 comprises:

-   -   drilling a hole through skull 42, typically at a posterior site        of the skull, and typically between 1 and 3 cm of sagittal        midplane 46 of skull 42;    -   introducing a catheter through the hole and into subarachnoid        space 50 or the gray or white matter of the brain, while a        lateral lead 72 is disposed along the catheter;    -   advancing the catheter within the brain to a more anterior site,        such as near the forehead; and    -   withdrawing the catheter while leaving lateral lead 72 in place        within the brain.

Lateral lead 72 is then electrically coupled to control circuitry 34, ifnot previously coupled prior to the implantation procedure.

This procedure is typically performed twice, once for each of left andright lateral leads 72A and 72B. Therefore, only two holes need to bemade through the skull in order to implant all of lateral treatmentelectrodes 32. A similar procedure may be employed for implantingmidplane lead 70 under skin 62; alternatively, midplane lead 70 isimplanted without the use of a catheter, such as by tunneling, asdescribed hereinabove with reference to FIG. 1A.

Reference is now made to FIG. 3, which is a schematic illustration ofyet another configuration of system 20, in accordance with anapplication of the present invention. Although this configuration isillustrated for the configuration of system 20 shown in FIG. 1A, it mayalso be used with the configurations shown in FIGS. 1B and 2. In thisconfiguration, electroosmotically driving the fluid comprises (a)detecting, by control circuitry 34, a voltage difference betweensubarachnoid space 50 and superior sagittal sinus 40, and (b) setting,by control circuitry 34, a level of the one or more treatment currentsresponsively to the detected voltage difference. For some applications,system 20 further comprises a single first detection electrode 120 and asingle second detection electrode 122. Single first detection electrode120 is implanted in subarachnoid space 50, and single second detectionelectrode 122 is implanted in superior sagittal sinus 40. For someapplications, detecting the voltage comprises detecting, by controlcircuitry 34, the voltage difference between first and second detectionelectrodes 120 and 122.

Reference is still made to FIG. 3. For some applications, system 20further comprises a hat 110, which comprises a wireless energytransmitter 112. When the subject wears the hat, transmitter 112 isdisposed in at vicinity of control circuitry 34 (which may be implantedsubcutaneously, as described above). Control circuitry 34 comprises awireless energy receiver to receive energy transmitted by transmitter112. Although described with reference to FIG. 3, hat 110 may also beimplemented in combination with any of the other configurations ofsystem 20 described herein, including those shown in FIGS. 1A, 1B, and2.

Reference is now made to FIG. 4, which is a schematic illustration ofsystem 20, in accordance with an application of the present invention.For some applications, system 20 comprises a housing 150, which containscontrol circuitry 34. For some applications, housing 150 is implantable,such as subcutaneous; for example, the housing may be similar toconventional pacemaker housings (“cans”). For some applications, housing150 comprises first, second, and third lead interfaces 154A, 1548, and154C, for electrical and mechanical coupling with midplane lead 70 andlateral leads 72. For example, first, second, and third lead interfaces154A, 154B, and 154C may comprise first, second, and third ports, intowhich corresponding connectors of the leads are inserted. Alternatively,the leads may have hardwired connections with the lead interfaces.First, second, and third lead interfaces 154A, 154B, and 154C are alsoelectrically coupled with control circuitry 34.

Typically, the lead interfaces are physically arranged such that secondlead interface 154B is between first and third lead interfaces 154A and154C on housing 150. Control circuitry 34 is configured to apply currentthrough second lead interface 154B to midplane lead 70 such thatmidplane treatment electrodes 30 are cathodes, and to apply currentthrough first, and third lead interfaces 154A and 154B such that lateraltreatment electrodes 32 are anodes.

Alternatively, for some applications, housing 150 comprises only twolead interfaces, and left and right lateral leads 72A and 72B areelectrically coupled to each other so as define a single, jointconnector, which is coupleable to one of the lead interfaces of thehousing.

As mentioned above with reference to FIGS. 1A-B, for some applicationssystem 20 comprises between 5 and 20 midplane treatment electrodes 30, acorresponding number of left lateral treatment electrodes 32A, and acorresponding number of right lateral treatment electrodes 32B. For someapplications, an average distance D2 between (a) longitudinally-adjacentpairs of midplane treatment electrodes 30, (b) longitudinally-adjacentpairs of first lateral treatment electrodes 32A, and (c)longitudinally-adjacent pairs of second lateral treatment electrodes 32Bis at least 1 cm, no more than 5 cm, and/or between 1 and 5 cm (e.g., 3cm), measured between longitudinal midpoints of the electrodes. For someapplications, each of midplane lead 70, left lateral lead 72A, and rightlateral lead 72B, when fully extended, has a length of at least 10 cm,no more than 40 cm (e.g., no more than 30 cm), and/or between 10 and 40cm (e.g., between 10 and 30 cm).

For some applications, system 20 comprises:

-   -   exactly three leads, consisting of a midplane lead 70, a left        lateral lead 72A, and a right lateral lead 72B;    -   at least five midplane treatment electrodes 30, which are        disposed (e.g., fixed) along midplane lead 70 at an average        distance of at least 1 cm, no more than 5 cm, and/or between 1        and 5 cm (e.g., 3 cm) between longitudinally-adjacent pairs of        midplane treatment electrodes 30, measured between longitudinal        midpoints of midplane treatment electrodes 30;    -   at least five left lateral treatment electrodes 32A, which are        disposed (e.g., fixed) along left lateral lead 72A at an average        distance of at least 1 cm, no more than 5 cm, and/or between 1        and 5 cm (e.g., 3 cm) between longitudinally-adjacent pairs of        left lateral treatment electrodes 32A, measured between        longitudinal midpoints of left lateral treatment electrodes 32A;    -   at least five right lateral treatment electrodes 32B, which are        disposed (e.g., fixed) along right lateral lead 72B at an        average distance of at least 1 cm, no more than 5 cm, and/or        between 1 and 5 cm (e.g., 3 cm) between longitudinally-adjacent        pairs of right lateral treatment electrodes 32B, measured        between longitudinal midpoints of right lateral treatment        electrodes 32B; and    -   housing 150, which comprises control circuitry 34, to which        midplane treatment electrodes 30, left lateral treatment        electrodes 32A, and right lateral treatment electrodes 32B are        electrically coupled via midplane lead 70, left lateral lead        72A, and right lateral lead 72B, respectively.

Control circuitry 34 is configured to:

-   -   configure midplane treatment electrodes 30 as cathodes, and left        and right lateral treatment electrodes 32A and 32B as left and        right anodes, respectively,    -   apply respective treatment currents between (a) (i) one or more        of midplane treatment electrodes 30 and (ii) one or more of left        lateral treatment electrodes 32A, and (b) (i) one or more of        midplane treatment electrodes 30 and (ii) one or more of right        lateral treatment electrodes 32B, and    -   configure the treatment currents to treat the subject by        electroosmotically driving fluid from, subarachnoid space 50 to        superior sagittal sinus 40.

Reference is made to FIGS. 1A-4. For any of the applications describedherein, system 20 may comprise:

-   -   a single midplane treatment electrode 30, rather than a        plurality of midplane treatment electrodes 30,    -   a single lateral treatment electrode 32, rather than a plurality        of lateral treatment electrodes 32,    -   a single left lateral treatment electrode 32A, rather than a        plurality of left lateral treatment electrodes 32A, and/or    -   a single right lateral treatment electrode 32B, rather than a        plurality of right lateral treatment electrodes 32B.

For some of these applications, any of these single electrodes comprisesan elongate electrode having a length of at least 10 cm, no more than 40cm (e.g., no more than 30 cm), and/or between 10 and 40 cm (e.g.,between 10 and 30 cm); for example, the elongate electrode may comprisean electrically-non-insulated wire.

Although the techniques described hereinabove have been described astreating the subject by electroosmotically driving fluid fromsubarachnoid space 50 to superior sagittal sinus 40, the techniques mayalternatively or additionally be used without electroosmosis.

It will be appreciated by persons skilled in the art that the presentinvention is not limited to what has been particularly shown anddescribed hereinabove. Rather, the scope of the present inventionincludes both combinations and subcombinations of the various featuresdescribed hereinabove, as well as variations and modifications thereofthat are not in the prior art, which would occur to persons skilled inthe art upon reading the foregoing description.

The invention claimed is:
 1. A method comprising: disposing midplanetreatment electrodes over a superior sagittal sinus, outside and inelectrical contact with a skull of a head of a subject identified as atrisk of or suffering from Alzheimer's disease; disposing lateraltreatment electrodes between 1 and 12 cm of a sagittal midplane of theskull; and treating the subject by electroosmotically driving fluid froma subarachnoid space to the superior sagittal sinus, by activatingcontrol circuitry to apply one or more treatment currents between (a)one or more of the midplane treatment electrodes and (b) one or more ofthe lateral treatment electrodes.
 2. The method according to claim 1,wherein treating the subject comprises facilitating clearance of amyloidbeta from the subarachnoid space to the superior sagittal sinus byelectroosmotically driving the fluid from the subarachnoid space to thesuperior sagittal sinus.
 3. The method according to claim 1, whereintreating the subject comprises facilitating clearance of metal ions fromthe subarachnoid space to the superior sagittal sinus byelectroosmotically driving the fluid from the subarachnoid space to thesuperior sagittal sinus.
 4. The method according to claim 1, whereindisposing the lateral treatment electrodes comprises disposing thelateral treatment electrodes outside and in electrical contact with theskull.
 5. The method according to claim 4, wherein disposing the lateraltreatment electrodes comprises disposing the lateral treatmentelectrodes between 4 and 12 cm of the sagittal midplane of the skull. 6.The method according to claim 4, wherein disposing the lateral treatmentelectrodes comprises disposing the lateral treatment electrodes outsidethe head.
 7. The method according to claim 6, wherein disposing thelateral treatment electrodes comprises disposing the lateral treatmentelectrodes on an external surface of the head.
 8. The method accordingto claim 4, wherein disposing the lateral treatment electrodes comprisesimplanting the lateral treatment electrodes under skin of the head. 9.The method according to claim 1, wherein disposing the midplanetreatment electrodes comprises disposing the midplane treatmentelectrodes outside the head.
 10. The method according to claim 9,wherein disposing the midplane treatment electrodes comprises disposingthe midplane treatment electrodes on an external surface of the head.11. The method according to claim 1, wherein disposing the midplanetreatment electrodes comprises implanting the midplane treatmentelectrodes under skin of the head.
 12. The method according to claim 1,wherein disposing the lateral treatment electrodes comprises implantingthe lateral treatment electrodes under an arachnoid mater of thesubject.
 13. The method according to claim 12, wherein disposing thelateral treatment electrodes comprises disposing the lateral treatmentelectrodes between 1 and 3 cm of the sagittal midplane of the skull. 14.The method according to claim 12, wherein disposing the lateraltreatment electrodes comprises disposing the lateral treatmentelectrodes in the subarachnoid space.
 15. The method according to claim12, wherein disposing the lateral treatment electrodes comprisesdisposing the lateral treatment electrodes in gray or white matter of abrain of the subject.
 16. The method according to claim 1, whereindisposing the midplane treatment electrodes comprises disposing themidplane treatment electrodes within 10 mm of the sagittal midplane ofthe skull.
 17. The method according to claim 1, wherein disposing themidplane treatment electrodes comprises disposing at least five midplanetreatment electrodes over the superior sagittal sinus.
 18. The methodaccording to claim 1, wherein activating the control circuitry comprisesactivating the control circuitry to configure the midplane treatmentelectrodes as cathodes, and the lateral treatment electrodes as anodes.19. The method according to claim 1, wherein the lateral treatmentelectrodes comprise left lateral treatment electrodes and right lateraltreatment electrodes, and wherein disposing the lateral treatmentelectrodes comprises disposing the left lateral treatment electrodesleft of the sagittal midplane of the skull, and disposing the rightlateral treatment electrodes right of the sagittal midplane of theskull.
 20. The method according to claim 19, wherein activating thecontrol circuitry comprises activating the control circuitry toconfigure the midplane treatment electrodes as cathodes, and the leftand the right lateral treatment electrodes as left and right anodes,respectively.
 21. The method according to claim 19, wherein activatingthe control circuitry to apply the one or more treatment currentsbetween (a) one or more of the midplane treatment electrodes and (b) oneor more of the lateral treatment electrodes comprises activating thecontrol circuitry to apply: a first treatment current between a firstone of the midplane treatment electrodes and a first one of the leftlateral treatment electrodes, a second treatment current between thefirst one of the midplane treatment electrodes and a first one of theright lateral treatment electrodes, a third treatment current between asecond one of the midplane treatment electrodes and a second one of theleft lateral treatment electrodes, and a fourth treatment currentbetween the second one of the midplane treatment electrodes and a secondone of the right lateral treatment electrodes.
 22. The method accordingto claim 1, wherein electroosmotically driving the fluid comprises:detecting, by the control circuitry, a voltage difference between thesubarachnoid space and the superior sagittal sinus; and setting, by thecontrol circuitry, a level of the one or more treatment currentsresponsively to the detected voltage difference.
 23. The methodaccording to claim 1, wherein activating the control circuitry comprisesactivating the control circuitry to apply the one or more treatmentcurrents as direct currents.
 24. A method comprising: disposing one ormore midplane treatment electrodes over a superior sagittal sinus,outside and in electrical contact with a skull of a head of a subjectidentified as at risk of or suffering from Alzheimer's disease;disposing one or more lateral treatment electrodes between 1 and 12 cmof a sagittal midplane of the skull; and treating the subject byelectroosmotically driving fluid from a subarachnoid space to thesuperior sagittal sinus, by activating control circuitry to apply one ormore treatment currents between (a) one or more of the midplanetreatment electrodes and (b) one or more of the lateral treatmentelectrodes.
 25. The method according to claim 24, wherein the one ormore lateral treatment electrodes comprise one or more left lateraltreatment electrodes and one or more right lateral treatment electrodes,and wherein disposing the one or more lateral treatment electrodescomprises disposing the one or more left lateral treatment electrodesleft of the sagittal midplane of the skull, and disposing the one ormore right lateral treatment electrodes right of the sagittal midplaneof the skull.
 26. The method according to claim 25, wherein activatingthe control circuitry comprises activating the control circuitry toconfigure the one or more midplane treatment electrodes as one or morecathodes, the one or more left lateral treatment electrodes as one ormore left anodes, and the one or more right lateral treatment electrodesas one or more right anodes.
 27. Apparatus for treating a subjectidentified as at risk of or suffering from Alzheimer's disease, theapparatus comprising: exactly three leads, consisting of a midplanelead, a left lateral lead, and a right lateral lead; at least fivemidplane electrodes, which are disposed along the midplane lead at anaverage distance of at least 1 cm between longitudinally-adjacent pairsof the midplane electrodes, measured between longitudinal midpoints ofthe midplane electrodes; at least five left lateral electrodes, whichare disposed along the left lateral lead at an average distance of atleast 1 cm between longitudinally-adjacent pairs of the left lateralelectrodes, measured between longitudinal midpoints of the left lateralelectrodes; at least five right lateral electrodes, which are disposedalong the right lateral lead at an average distance of at least 1 cmbetween longitudinally-adjacent pairs of the right lateral electrodes,measured between longitudinal midpoints of the right lateral electrodes;and a housing, which comprises control circuitry, to which the midplane,the left lateral, and the right lateral electrodes are electricallycoupled via the midplane lead, the left lateral lead, and the rightlateral lead, respectively, the control circuitry configured to:configure the midplane treatment electrodes as cathodes, and the leftand the right lateral treatment electrodes as left and right anodes,respectively, apply respective treatment currents between (a) (i) one ormore of the midplane treatment electrodes and (ii) one or more of theleft lateral treatment electrodes, and (b) (i) one or more of themidplane treatment electrodes and (ii) one or more of the right lateraltreatment electrodes, and configure the treatment currents to treat thesubject by electroosmotically driving fluid from a subarachnoid space toa superior sagittal sinus of the subject.